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| United States Patent |
5,531,861
|
|
Yu
, et al.
|
July 2, 1996
|
Chemical-mechanical-polishing pad cleaning process for use during the
fabrication of semiconductor devices
Abstract
A chemical-mechanical-polishing process in which energy is imparted to a
polishing pad (18) dislodging particles (46), which are removed by vacuum
withdrawal to continuously clean the surface of the polishing pad (14).
Energy is imparted to polishing pad (18) by either sonic energy from
acoustic waves, or by physical impaction. The acoustic waves are generated
by submerging a transducer (28) in the polishing slurry (18). The
transducer (28) is powered by a voltage amplifier (30) coupled to a
computer controlled-frequency generator (32). The acoustic wave frequency
is adjusted by the frequency generator (32) to induce sonic vibration in
the polishing pad (14) such that particles (46) are continuously dislodged
from polishing pad (14). Physical impaction is performed by an impaction
tool (48) coupled to a vacuum head (33).
| Inventors:
|
Yu; Chris C. (Irvine, CA);
Yu; Tat-Kwan (Austin, TX)
|
| Assignee:
|
Motorola, Inc. (Schaumburg, IL)
|
| Appl. No.:
|
373804 |
| Filed:
|
January 17, 1995 |
| Current U.S. Class: |
438/693; 134/1; 134/21; 216/88; 216/89; 438/959 |
| Intern'l Class: |
H01L 021/306; H01L 021/304; B08B 003/12; B08B 005/02 |
| Field of Search: |
156/636
134/21,1
437/228
216/288,289
|
References Cited
U.S. Patent Documents
| 3089790 | May., 1963 | Balamuth et al. | 134/21.
|
| 3915739 | Oct., 1975 | Maahs et al. | 134/21.
|
| 4414244 | Nov., 1983 | Timberlake et al. | 427/105.
|
| 4680893 | Jul., 1987 | Cronkhite et al. | 51/5.
|
| 4956024 | Sep., 1990 | Dean et al. | 134/37.
|
| 5240552 | Aug., 1993 | Yu et al. | 156/636.
|
| 5245796 | Sep., 1993 | Miller et al. | 51/283.
|
| 5320706 | Jul., 1994 | Blackwell | 156/636.
|
| 5330577 | Jul., 1994 | Maeda et al. | 118/722.
|
| 5399234 | Mar., 1995 | Yu et al. | 156/636.
|
| Foreign Patent Documents |
| 0226931 | Jan., 1987 | EP | .
|
| 63-185556 | Jan., 1987 | JP | .
|
| 04-135173 | Sep., 1990 | JP | .
|
Primary Examiner: Kunemund; Robert
Assistant Examiner: Whipple; Matthew L.
Attorney, Agent or Firm: Dockrey; Jasper W.
Parent Case Text
This is a continuation-in-part of application Ser. No. 08/143,020, now U.S.
Pat. No. 5,399,234, filed Sep. 29, 1993.
Claims
We claim:
1. A chemical-mechanical-polishing process for fabricating a semiconductor
device comprising the steps of:
providing a polishing apparatus having a polishing pad submerged in a
liquid;
imparting a dislodging force to the polishing pad; and
removing polishing debris from the polishing pad by vacuum withdrawal.
2. The process of claim 1, wherein the step of imparting a dislodging force
comprises generating acoustic waves.
3. The process of claim 1, wherein the step of imparting a dislodging force
comprises physical impaction of the polishing pad.
4. The process of claim 1, wherein the step of providing a liquid comprises
providing a liquid selected from the group consisting of a polishing
slurry and water.
5. The process of claim 1 further comprising submerging a semiconductor
substrate in the liquid.
6. A chemical-mechanical-polishing process for fabricating a semiconductor
device comprising the steps of:
providing a polishing pad submerged in a polishing slurry for the removal
of a material layer from a semiconductor substrate;
submerging a semiconductor substrate in the polishing slurry;
imparting energy to the polishing pad to dislodge polishing debris from the
polishing pad; and
removing the polishing debris from the polishing pad by vacuum withdrawal.
7. The process of claim 6, wherein the step of imparting energy comprises
imparting acoustic energy.
8. The process of claim 6, wherein the step of imparting energy comprises
physical impaction of the polishing pad with a blunt object.
9. The process of claim 8, wherein the blunt object comprises a member
protruding from a vacuum device.
10. A chemical-mechanical-polishing process for fabricating a semiconductor
device comprising the steps of:
providing a polishing apparatus having a polishing pad submerged in a
polishing slurry;
submerging a semiconductor substrate in the polishing slurry, the substrate
having a surface;
polishing the surface with the polishing pad to remove material from the
surface;
generating acoustic waves in the polishing slurry, wherein the acoustic
waves continuously dislodge material from the polishing pad; and
removing dislodged material from the polishing pad by vacuum withdrawal.
11. The process of claim 10, wherein the step of generating acoustic waves
comprises submerging an acoustic transducer in the polishing slurry and
applying electrical power to the transducer.
12. The process of claim 10, wherein the step of generating acoustic waves
comprises placing acoustic transducer in contact with the polishing pad
and inducing acoustic vibration within the polishing pad.
Description
FIELD OF THE INVENTION
This invention relates in general to a method for fabricating a
semiconductor device, and more particularly, to a method for polish
planarizing a material layer in a semiconductor device using a
chemical-mechanical-polishing apparatus.
BACKGROUND OF THE INVENTION
The increasing need to form planar surfaces in semiconductor device
fabrication has led to the development of process technology known as
chemical-mechanical-polishing (CMP). In the CMP process, semiconductor
substrates are rotated against a polishing pad in the presence of an
abrasive slurry. Most commonly, the layer to be planarized is an
electrically insulating layer overlying active circuit devices. As the
substrate is rotated against the polishing pad, the abrasive force
polishes away the surface of the insulating layer. Additionally, chemical
compounds within the slurry undergo a chemical reaction with the
components of the insulating layer to enhance the rate of removal. By
carefully selecting the chemical components of the slurry, the polishing
process can be made more selective to one type of material than another.
For example, in the presence of potassium hydroxide, silicon dioxide is
removed at a faster rate than boron nitride. The ability to control the
selectivity of a CMP process has led to its increased use in the
fabrication of complex integrated circuits.
A common requirement of all CMP processes is that the substrate be
uniformly polished. In the case of polishing a electrically insulating
layer, it is desirable to polish the layer uniformly from edge to edge on
the substrate. To ensure that a planar surface is obtained, the
electrically insulating layer must be uniformly removed. Uniform polishing
can be difficult because, typically, there is a strong dependence of the
polish removal rate on localized variations in the surface topography of
the substrate. For example, in substrate areas having a high degree of
surface variation, such as areas having closely spaced active devices, the
polishing rate is higher than in areas lacking a high degree of surface
contrast. Additionally, the polishing rate at the center of substrate may
differ from the polishing rate at the edge of the substrate.
To compensate for the varying removal rates at different locations on the
substrate surface, the polishing process is extended to ensure that a
planar surface is obtained. A hard, thin-film, referred to as a
polish-stop layer, can be used to prevent the unwanted removal of material
in the underlying device layers during extended polishing. If the
polish-stop material is sufficiently resistant to abrasive removal, and
the polishing slurry is selective to the polish-stop material, the
polishing time can be extended until the passivation layer is uniformly
polished, without damaging underlying layers. To be selective to the
polish-stop layer, the chemical components in the slurry must be
substantially unreactive with the polish-stop material. Common polish-stop
materials include silicon nitride and boron nitride, and the like. In the
absence of a polish-stop layer, over-polishing can occur resulting in
unwanted removal of underlying layers.
To ensure that uniform polishing action is obtained, it is important that
the rate of material removal remain constant. Changes in the surface
texture of the polishing pad during the polishing process reduce the
degree of abrasiveness of the polishing pad. In particular, during the
polishing of an insulating material, such as silicon dioxide, reaction
products generated in the polishing slurry, and other debris, collect on
the surface of the polishing pad. The collected material fills micropores
in the surface of the polishing pad, which is known as glazing. When the
micropores become filled with residue from the polishing process, the
polishing rate declines. In extreme cases, a decline in polish removal
rate can result in an incomplete removal of material leading to a
degradation in polishing uniformity. This is because the polishing process
is controlled by specifying a time interval for completion of the
polishing process. The time interval is calculated based upon a specific
and constant polish removal rate.
In order to avoid degradation in the polish removal rate caused by glazing
the surface of the polishing pad, the pad is abraded by a conditioner,
such as a steel brush. In the abrasion process, material is removed from
the surface of the pad by a mechanical grinding process. This process
results in removing material from the pad itself in addition to reaction
products and debris from the polishing process. Changes in the surface
structure of the polishing pad can result in process instability and
reduced usable lifetime of the polishing pad.
While CMP potentially offers wide versatility, and the ability to form
surfaces with a high degree of planarity, the polishing process must be
carefully controlled to maintain optimum process performance. To date,
methods to improve processing performance have included the development of
high selectivity polishing slurries, and the development of various
materials for use as polish-stop layers. However, further development is
necessary to provide process parameter stability.
SUMMARY OF THE INVENTION
In practicing the present invention there is provided an improved polishing
process for the fabrication of semiconductor devices. A
chemical-mechanical-polishing process used to form a planarized layer in
semiconductor devices is carried out in which the polishing pad is
continuously cleaned by imparting energy to the polishing pad, and
applying vacuum withdrawal to remove polishing debris dislodged from the
polishing pad. The invention can be practiced either during device
processing, or independently in a separate cleaning step. In one
embodiment, a polishing apparatus is provided, which includes a polishing
pad submerged in a liquid. A dislodging force is applied to the polishing
pad and polishing debris dislodged by the applied force are removed by
vacuum withdrawal.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic diagram of a polishing apparatus arranged in
accordance with one embodiment of the invention;
FIG. 2 illustrates, in cross-section, a portion of a semiconductor
substrate having a material layer to be polished; and
FIG. 3 illustrates, in cross-section, a portion of a polishing pad;
FIG. 4 illustrates, in cross-section, the removal of polishing debris in
accordance with the invention;
FIG. 5 is a schematic diagram of a polishing apparatus arranged in
accordance with another embodiment of the invention; and
FIG. 6 illustrates, in cross-section, the removal of polishing debris in
accordance with yet another embodiment of the invention.
It will be appreciated that for simplicity and clarity of illustration,
elements shown in the Figures have not necessarily been drawn to scale.
For example, the dimensions of some of the elements are exaggerated
relative to each other for clarity. Further, where considered appropriate,
reference numerals have been repeated among the Figures to indicate
corresponding elements.
DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS
The present invention provides an improved chemical-mechanical-polishing
process for fabrication of semiconductor devices. In one embodiment,
acoustic waves are generated within a polishing slurry, while polishing
the surface of a semiconductor substrate. The generation of acoustic waves
in the slurry provides a means of cleaning the surface of a polishing pad
during the polishing process. The acoustic waves provide a constant
agitation in the slurry, which prevents the clogging of micropores in the
polishing pad by polishing debris suspended in the slurry. The polishing
debris dislodged by the acoustic waves are removed from the surface of the
polishing pad by vacuum withdrawal. In another embodiment, an impaction
force is applied to the polishing pad by an indenter attached to a vacuum
head. The indenter imparts sufficient energy to the pad to dislodge
polishing debris. The debris are removed by vacuum withdrawal through the
vacuum head. The continuous removal of polishing debris from the polishing
pad assists in maintaining a constant polishing rate during the polishing
process.
Shown in FIG. 1 is a schematic diagram of a polishing apparatus 10 arranged
in accordance with the invention. Polishing apparatus 10 includes a
polishing platen 12 which supports a polishing pad 14. Both polishing
platen 12 and polishing pad 14 are bounded by a slurry retaining wall 16.
Polishing pad 14 is submerged in a polishing slurry 18, which is confined
to the area of the pad by retaining wall 16. A semiconductor substrate 20,
which is to be planarized, is held against polishing pad 14 by a substrate
carrier 22. Substrate carrier 22 includes a movable support arm 24 for
bringing substrate 20 into contact with polishing pad 14, and a substrate
support 26. Substrate support 26 includes a carrier holder and an
elastomeric pad (not shown) for holding substrate 20. Those skilled in the
art will recognize the previously described features as those of a
conventional polishing tool.
In operation, substrate 20 is polished by an abrasive action created by the
rotational action of polishing pad 14 and substrate 20. Polishing slurry
18 is a colloidal composition containing an abrasive, such as silica
particles, suspended in a solution of potassium hydroxide (KOH) and water.
Additional chemicals are sometimes added to the slurry to adjust the pH,
and to aid in suspending abrasives. During polishing, polishing slurry 18
serves to lubricate the surface of polishing pad 14, and to create an
abrasive action at the surface of substrate 20. In addition, the chemicals
in the slurry undergo a chemical reaction at the substrate surface, which
assists in removing layers of material from the substrate.
Shown in FIG. 2, in cross-section, is a portion of semiconductor substrate
20 supporting representative material layers commonly used to fabricate
semiconductor devices, such as integrated circuits, and the like. In the
exemplary structure, an active device layer 36 overlies semiconductor
substrate 20. Active device layer 36 contains various components commonly
present in a semiconductor device, such as transistors, resistors,
capacitors, and the like. The components are fabricated in active regions
which are electrically isolated by field isolation regions. Typically, the
components are comprised of patterned layers of semiconductor and
refractory metal materials. The components are covered by an insulating
material to electrically isolate the components from overlying layers of
conductive material. Contact openings are present in the insulating layer
to permit electrical contact by overlying interconnect leads. The
interconnect leads are typically fabricated in one or more overlying metal
interconnect layers.
A metal interconnect layer 38 is shown in FIG. 2 overlying active device
layer 36. Metal interconnect layer 38 is covered by an insulation layer
40. Although the exact material compositions can vary, in many integrated
circuits layer 40 is an insulating material, such as silicon dioxide,
silicon nitride, silicate glass, and the like. Metal interconnect layer 38
is typically an electrically conductive metal, such as aluminum alloyed
with silicon, or aluminum alloyed with silicon and copper. Alternatively,
interconnect layer 38 can be a refractory metal such as tungsten, titanium
tungsten, and other refractory metal alloys.
In a polish planarization process, for example, insulation layer 40 is
polished by the abrasive action of the polishing pad 14 and polishing
slurry 18. Shown in FIG. 3, in cross-section, is a portion of polishing
pad 14. Polishing pad 14 is constructed of an open-pore polyurethane
material. Micropores 42 are interspersed throughout the polyurethane
material of polishing pad 14. During the polishing process, chemical
reaction products and abrasives in the slurry accumulate and form a solid
layer of polishing debris 44 on the surface of polishing pad 14. This
phenomenon is known as "glazing." Glazing of the polishing pad reduces the
polishing rate because the mass transfer rate of the polishing slurry is
reduced. The transport of polishing slurry 18 between micropores 42 is
essential in maintaining a flow of abrasives and reaction products to and
from the surface of substrate 20. When micropores 42 become clogged by
particles from polishing debris layer 44, the reduced mass transfer rate
creates process instability and a general reduction in polishing rate.
To overcome the instability caused by glazing of the polishing pad, in one
embodiment of the inventive process, a transducer 28 is submerged in
polishing slurry 18. Transducer 28 is powered by a voltage amplifier 30,
which amplifies an AC electrical voltage signal from a computer-controlled
frequency generator 32. Voltage amplifier 30 is capable of providing
100-500 Watts of AC power to transducer 28. Frequency generator 32 is
capable of modulating the electrical voltage signal at transducer 28 in
the range of 100 Hz to 1 MHz. When power is applied to transducer 28,
acoustic waves are induced in polishing slurry 18. Transducer 28 can be a
piezoelectric material such as metallized quartz, or a metallized titanate
material, such as lead zirconium titanate, and the like. Transducer 28 is
submerged in polishing slurry 18 to enhance the coupling efficiency of the
acoustic waves at the transducer to the slurry. The acoustic waves
permeate throughout polishing slurry 18 and have an amplitude proportional
to the power applied to transducer 28. A resonant vibrational frequency is
induced in polishing slurry 18, which dislodges material from the surface
of polishing pad 14.
A vacuum head 33 rides on the surface of polishing pad 14, as illustrated
in FIG. 1. Vacuum head 33 is coupled to a vacuum pumping system 34 by a
vacuum line 35. Vacuum head 33 is either completely or partially submerged
in polishing slurry 18. Liquid polishing slurry and polishing debris are
drawn through vacuum head 33 by vacuum pressure created by vacuum system
34. In an optional method of the invention, the polishing debris is
filtered out of the polishing slurry and the filtered slurry is returned
to polishing apparatus 10 by mean of a slurry return line (not shown).
FIG. 4 illustrates, in cross-section, a portion of polishing pad 14
undergoing a cleaning process in accordance with one embodiment of the
invention. Transducer 28 imparts acoustical energy to polish pad 14, which
dislodges particles 46 from micropores 42. Once the particles are
dislodged, they are drawn into vacuum head 33 by vacuum pressure generated
by vacuum system 34. Transducer 28 imparts sufficient energy to polishing
pad 14 such that a vibrational motion is created in polishing pad 14. The
vibrational motion is of sufficient energy to break up slurry debris layer
14, and to dislodge particles trapped in micropores 42.
In an alternative method, water is forced through micropores 42 of
polishing pad 14. The use of water to clean polishing pad 14 requires that
polishing apparatus 10 be taken off-line and a special cleaning process
carried out. Polishing slurry 18 is drained away, and a small amount of
water is applied to the surface of polishing pad 14. The cleaning can be
performed by either rotating polishing platen 12 while holding vacuum head
33 stationary, or alternatively, by drawing vacuum head 33 is across the
surface of polishing pad 14.
Another embodiment of the invention is illustrated in the schematic diagram
shown in FIG. 5. In this embodiment, voltage amplifier 30 powers a
piezoelectric transducer 47, which is in contact with polishing pad 14. In
operation, an acoustic wave is transmitted to polishing pad 14 from
transducer 47 at a frequency ranging from about 100 Hz to 1 MHz. The
acoustic waves impart vibrational energy to polishing pad 14. The
vibration continuously breaks up solid residue on the surface of polishing
pad 14, thereby improving the efficiency of the polishing process. The
abrasiveness of polishing pad 14 is maintained at a high level by
continuously removing reaction products and polishing debris from the
surface of polishing pad 14. Additionally, by continuously cleaning the
surface of pad 14, polishing apparatus 10 does not have to be shut down or
otherwise interrupted for either a manual cleaning of the polishing pad,
or for performing a process cleaning cycle. The continuous cleaning of the
polishing pad results in longer periods of operation with shorter periods
of down-time for cleaning maintenance. Thus, the continuous removal of
material from the surface of polishing pad 14 results in maintaining a
high polishing rate, and longer hours of continuous operation.
In order to optimize the acoustic energy transmitted to polishing pad 14,
computer-controlled frequency generator 32 modulates the input signal to
transducer 47 at the resonant frequency of polishing slurry 18 and
polishing pad 14. For example, a sustained vibration can be induced in the
polishing pad and the slurry by generating an acoustic wave having a
frequency of preferably about 1 kHz at about 100 to 500 Watts. By
transmitting acoustic waves at the resonant frequency of the slurry and
the pad, maximum vibrational energy is achieved. Of course, the acoustic
wave frequency must be varied depending upon the physical dimensions and
composition of the polishing pad and the underlying platen. For example,
in a polishing system having a platen diameter of one meter, the
operational range of the transducer is preferably about 1 to 5 kHz.
FIG. 6 illustrates, in cross-section, a portion of polishing pad 14
undergoing a cleaning process in accordance with yet another embodiment of
the invention. In the alternative embodiment, particles 46 are dislodged
from micropores 42 and from the surface of polishing pad 14 by means of
mechanical deformation. Means for mechanically deforming polishing pad 14
are contained within vacuum head 33. As vacuum head 33 moves across the
surface of polishing pad 14, as shown by the directional arrow in FIG. 6,
the surface of polishing pad 14 is mechanically deformed. An indenter 48
protrudes from vacuum head 33 and makes physical contact with the surface
of polishing pad 14, and with polished debris layer 44. A vacuum section
50 of vacuum head 33 creates a low pressure region, which draws particles
46 away from polishing pad 14 and into vacuum section 50.
Damage to polishing pad 14 is avoided because the rounded surface of
indenter 48 prevents any physical damage to the polished pad material.
Although illustrated in FIG. 6 as a blunt object, indenter 48 can be
formed by a variety of different mechanical devices. In the embodiment of
the invention illustrated in FIG. 6, the cleaning process can be carried
out by any impaction means capable of resenting a physical impaction force
to polishing pad 14.
The cleaning process of the present invention avoids deleterious effects to
the polishing pad by continuously blowing liquid through the micropores of
the polishing pad. Both the acoustic vibrational technique and the
physical impaction technique will not alter the surface roughness of
polishing pad 14.
In a further embodiment, the dislodging force is exclusively provided by
the vacuum pressure generated at vacuum head 33. The vacuum pressure is
adjusted to a level sufficient to dislodge slurry debris from the surface
of polishing pad 14 without the assistance of another energy source. The
vacuum process provides a simplified, low cost cleaning process with
minimal physical contact with the polishing pad. As in the other
embodiments, the vacuum pressure method can be carried out either during
wafer polishing, or in a separate off-line cleaning step.
Thus it is apparent that there has been provided, in accordance with the
invention, an acoustically regulated polishing process which fully meets
the advantages set forth above. By maintaining consistent surface texture
of polishing pad 14, improved polishing process stability is obtained.
Although the invention has been described and illustrated with reference
to specific illustrative embodiments thereof, it is not intended that the
invention be limited to those illustrative embodiments. Those skilled in
the art will recognize that variations and modifications can be made
without departing from the spirit of the invention. For example, many
different styles of vacuum systems can be used, including several
different kinds of commonly available liquid vacuum pumps. Furthermore,
vacuum throttling mechanisms can be used to vary the vacuum pressure
applied at the surface of the polishing pad. It is therefore intended to
include within the invention all such variations and modifications as fall
within the scope of the appended claims and equivalents thereof.
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